An ion wind device for a disposable glove machine

Abstract

The utility model discloses a disposable glove machine's ion wind device, ion wind utensil technical field, including locating plate, and the two locating holes are established in the both sides of locating plate top surface, and the vertical fixed connection of locating plate both sides has the support frame, and the outlet assembly is equipped in locating plate upper end, the utility model discloses the cooperation of screwing button and bolt, the angle adjustment of shell is controlled conveniently, is adjusted according to the angle of glove machine discharge port, and the most ion is blown to the glove as far as possible, avoids the adhesion of glove, through the cooperation of adjusting knob and speed sensor, the wind speed of ion fan is adjusted according to the speed of glove machine discharge, and it is convenient to eliminate the static electricity of all gloves, through the cooperation of bidirectional screw rod and servo motor, the coverage of ion fan is changed according to the different row of different glove machine discharge gloves, avoids some plastic gloves without eliminating static electricity, the device improves work efficiency, and saves the physical strength of staff.

Description

Technical Field

[0001] This utility model relates to the field of ion wind equipment technology, and in particular to an ion wind device for a disposable glove machine. Background Technology

[0002] With societal development, people are increasingly concerned about the hygiene of disposable products in medical care, catering, work, and daily life in order to improve environmental quality and personal hygiene. For example, disposable gloves: existing disposable glove machines heat-press plastic granules into plastic gloves. However, after the gloves are formed, static electricity is generated between them, causing multiple gloves to stick together. This makes it difficult for packaging personnel to separate the stuck gloves and pack them, requiring a lot of physical labor and wasting time. Therefore, improvements are needed to address these issues. Utility Model Content

[0003] The purpose of this invention is to address the shortcomings of existing technologies by proposing an ionization air device for disposable glove machines.

[0004] To achieve the above objectives, the present invention adopts the following technical solution: an ion air device for a disposable glove machine, comprising a positioning plate, two positioning holes on both sides of the top surface of the positioning plate, and support frames vertically fixed to both sides of the positioning plate, with a housing horizontally disposed between the two support frames, bolts fixed to the middle of both sides of the housing, the bolts being rotatably connected to the upper end of the support frame, and a tightening torsion block being threaded to the outer side of the bolt, the tightening torsion block being placed on the outer side of the support frame, and an air outlet assembly disposed at the upper end of the positioning plate.

[0005] Preferably, the air outlet assembly includes a dustproof cloth horizontally disposed on the top rear end of the positioning plate. The four ends of the dustproof cloth are fixed to the rear end face of the housing by positioning bolts. The rear end of the housing is provided with a ventilation opening that cooperates with the dustproof cloth, and the front end face of the housing is provided with an air outlet. A grille is installed inside the air outlet.

[0006] Preferably, the left rear end of the housing has an installation port, and a door panel is hinged to the rear end of the installation port. The rear end of the housing is provided with a bidirectional lead screw and a guide rod respectively. The right end of the bidirectional lead screw is connected to the output shaft of the servo motor, and the servo motor is installed on the inner bottom surface of the rear end of the housing.

[0007] Preferably, both ends of the guide rod are fitted with ion fans, and the lower rear ends of both ion fans are threaded to bidirectional lead screws.

[0008] Preferably, a power supply and a speed sensor are respectively installed at both ends inside the housing. The speed sensor is connected to a microcontroller via a wire, the microcontroller is connected to an ion fan via a wire, and the microcontroller is connected to an adjustment knob, which is installed on an inclined surface on the outside of the housing.

[0009] Compared with the prior art, the beneficial effects of this utility model are as follows: The combination of tightening buttons and bolts facilitates the adjustment of the outer shell angle, allowing for adjustment based on the angle of the glove machine's discharge port, maximizing the amount of ions blown onto the gloves and preventing them from sticking together; the combination of adjusting knobs and speed sensors allows for adjusting the ion fan speed according to the glove machine's discharge speed, facilitating the elimination of static electricity from all gloves; the combination of bidirectional lead screws and servo motors allows for adjusting the ion fan's coverage area based on the different number of rows of gloves discharged from different glove machines, preventing some plastic gloves from failing to eliminate static electricity; this device improves work efficiency and saves the physical labor of workers. Attached Figure Description

[0010] The accompanying drawings, which are included to provide a further understanding of the present invention and form part of this application, illustrate exemplary embodiments of the present invention and, together with the description thereof, serve to explain the present invention and do not constitute an undue limitation thereof. In the drawings:

[0011] Figure 1 This is a schematic diagram of the overall three-dimensional structure proposed in this utility model;

[0012] Figure 2 This is a schematic diagram of the overall rear three-dimensional structure proposed in this utility model;

[0013] Figure 3 This is a schematic diagram of the internal three-dimensional structure of the device proposed in this utility model;

[0014] Figure 4 The present utility model proposes Figure 3 Enlarged schematic diagram of the structure at part A in the middle.

[0015] The following are the components listed in the diagram: 1. Positioning plate; 2. Support frame; 3. Outer shell; 4. Tightening block; 5. Dustproof cloth; 6. Door panel; 7. Grille; 8. Ionizing fan; 9. Two-way lead screw; 10. Guide rod; 11. Servo motor; 12. Power supply; 13. Speed ​​sensor; 14. Adjustment knob. Detailed Implementation

[0016] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.

[0017] Example: See Figure 1-4 This utility model discloses an ionization air device for a disposable glove machine, comprising a positioning plate 1 for easy connection to a support frame 2; two positioning holes are provided on both sides of the top surface of the positioning plate 1 for easy installation of the device on other devices; and support frames 2 are vertically fixed to both sides of the positioning plate 1 for easy support of the outer shell 3 and internal components; the outer shell 3 is horizontally provided between the two support frames 2 for easy installation of other components; bolts are fixed to the middle of both sides of the outer shell 3 for easy adjustment of the angle of the outer shell 3; the bolts are rotatably connected to the upper end of the support frame 2, and a tightening torsion block is threaded on the outer side of the bolt. 4. The outer shell 3 is easily fixed by tightening the torsion block 4; the torsion block 4 is placed on the outside of the support frame 2, and the upper end of the positioning plate 1 is provided with an air outlet assembly; the air outlet assembly includes a dustproof cloth 5 horizontally arranged on the top surface of the rear end of the positioning plate 1, which prevents dust from entering and avoids excessive dust causing the servo motor 11 and ion fan 8 to overheat and malfunction; the four ends of the dustproof cloth 5 are fixed to the rear end face of the outer shell 3 by positioning bolts, the rear end of the outer shell 3 is provided with a ventilation port that cooperates with the dustproof cloth 5, and the front end face of the outer shell 3 is provided with an air outlet, and a grille 7 is installed in the air outlet to prevent debris from blocking the ion air and preventing it from blowing out.

[0018] In this utility model, an installation port is provided at the rear left side of the outer casing 3, and a door panel 6 is hinged to the rear end of the installation port, facilitating the replacement of the ion blower 8. Furthermore, a bidirectional lead screw 9 and a guide rod 10 are horizontally provided at the rear end of the inner casing 3. The bidirectional lead screw 9 facilitates the control of the distance between the two ion blowers 8, and the guide rod 10 facilitates the control of the movement direction of the two ion blowers 8. The right end of the bidirectional lead screw 9 is connected to the output shaft of the servo motor 11, facilitating the rotation of the bidirectional lead screw 9. The servo motor 11 is mounted on the inner bottom surface of the rear end of the outer casing 3. Ion blowers 8 are sleeved at both ends of the guide rod 10, facilitating the blowing of ionized air. The lower rear ends of both ion blowers 8 are threadedly connected to the bidirectional lead screw 9. A power supply 12 and a speed sensor 13 are respectively installed at both ends inside the outer casing 3, facilitating the replacement of the ion blower 8. The ion fan 8 is started. The speed sensor 13 (model E6A2-CS3C) is used to sense the glove delivery speed in real time. The speed sensor 13 is connected to the microcontroller via a wire, transmitting the collected glove delivery frequency signal to the microcontroller (model TMS320F28P550SG). The power supply 12 is connected to the ion fan 8 via a wire. The speed sensor 13 is connected to the microcontroller via a wire. The microcontroller is also connected to the ion fan 8 via a wire and to the adjustment knob 14. The adjustment knob 14 is installed on the inclined surface of the outer shell 3. The connection between the adjustment knob 14 and the microcontroller allows for manual input of wind speed adjustment commands, and manual adjustment has a lower priority than automatic control mode.

[0019] Working principle: When using the ion air device for disposable glove machines, the entire process from preparation to completion is as follows: At the start of use, the device is first installed and secured. Using suitable connectors, the device is securely installed in the corresponding position on the glove machine through the two positioning holes on both sides of the top surface of the positioning plate 1, completing the connection and fixation between the device and the glove machine, laying the foundation for subsequent work. After installation, the angle of the outer shell is adjusted. The tightening block 4, which is threaded onto the bolt on the outer side of the support frame 2, is rotated counterclockwise. Since the bolt is rotatably connected to the upper end of the support frame 2 and fixed to the middle of both sides of the outer shell 3, the outer shell 3 can rotate freely after the tightening block 4 is loosened. The air outlet on the front face of the outer shell 3 is aligned with the gloves on the glove conveying path. After adjusting to a suitable angle, the tightening block 4 is rotated clockwise to press tightly against the support frame 2, thereby fixing the angle of the outer shell 3 and ensuring that the ion air can be accurately blown onto the gloves.

[0020] Subsequently, the distance between the two ion blowers 8 is adjusted according to the number of rows of gloves being fed. If there are more than three rows of gloves being fed, the servo motor 11 is started and rotated clockwise. The output shaft of the servo motor 11 drives the bidirectional lead screw 9 to rotate clockwise. Because the lower ends of the ion blowers 8 at both ends are threaded to the bidirectional lead screw 9, and the ion blowers 8 are sleeved on the guide rod 10, under the action of the bidirectional lead screw 9, the ion blowers 8 at both ends will move away from each other along the guide rod 10 to blow ions onto more rows of gloves as much as possible. If there are fewer than three rows of gloves being fed... The servo motor 11 is controlled to rotate counterclockwise, and the bidirectional lead screw 9 rotates counterclockwise accordingly. The ion fans 8 at both ends move closer to each other along the guide rod 10 to ensure that the most ions are concentrated and blown onto the glove. During the operation of the device, the power supply 12 supplies power to the ion fans 8 and other components, enabling them to work normally and blow out ion air. The grille 7 inside the air outlet at the front of the outer shell 3 can prevent debris from entering and blocking the output of ion air. The dustproof cloth 5 at the rear of the outer shell 3 can prevent dust from entering the interior through the ventilation opening, preventing dust from causing the servo motor 11 and ion fans 8 to overheat and malfunction.

[0021] Meanwhile, the speed sensor 13 (model E6A2-CS3C) will sense the conveying speed of the glove in real time and transmit the collected glove conveying frequency signal to the microcontroller (model TMS320F28P550SG) through a wire. The microcontroller will automatically adjust the wind speed of the ion fan 8 according to the signal to achieve automatic wind speed control. If manual wind speed adjustment is required, the adjustment knob 14 installed on the inclined surface of the outer shell 3 can be rotated. The adjustment knob 14 is connected to the microcontroller and can input manual wind speed adjustment commands, but the priority of manual adjustment is lower than that of automatic control mode. When the ion fan 8 needs to be replaced, the hinged door 6 at the mounting port on the left rear side of the shell 3 can be opened for operation. After use, turn off the power of the device to complete the entire usage process.

[0022] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.

Claims

1. An ion wind device for a disposable glove machine comprising a positioning plate (1), characterized in that: Two positioning holes are formed in the top surface of the positioning plate (1), vertical support frames (2) are fixed on the two sides of the positioning plate (1), an outer shell (3) is horizontally arranged between the two ends of the support frames (2), bolts are fixed on the two sides of the middle part of the outer shell (3), the bolts are rotatably connected to the upper ends of the support frames (2), the outer sides of the bolts are threadedly connected with rotating torsion blocks (4), the rotating torsion blocks (4) are arranged on the outer sides of the support frames (2), and an air outlet assembly is arranged on the upper end of the positioning plate (1).

2. An ion wind device for a disposable glove machine according to claim 1, characterized in that: The dustproof cloth (5) is fixed on the rear end surface of the outer shell (3) through positioning bolts, a ventilation opening is formed in the rear end of the outer shell (3) and matched with the dustproof cloth (5), an air outlet opening is formed in the front end surface of the outer shell (3), and a grille (7) is arranged in the air outlet opening.

3. An ion wind device for a disposable glove machine according to claim 2, characterized in that: A mounting opening is formed in the left rear end of the outer shell (3), a door plate (6) is hingedly connected to the rear end of the mounting opening, a bidirectional screw rod (9) and a guide rod (10) are horizontally arranged in the rear end of the inner part of the outer shell (3), the right end of the bidirectional screw rod (9) is connected with the output shaft of a servo motor (11), and the servo motor (11) is arranged on the inner bottom surface of the rear end of the outer shell (3).

4. An ion wind device for a disposable glove machine according to claim 3, characterized in that: Ion air fans (8) are sleeved on the two ends of the guide rod (10), and the lower ends of the two ion air fans (8) are threadedly connected with the bidirectional screw rod (9).

5. The ion wind device for a disposable glove machine according to claim 1, wherein: A power supply (12) and a speed sensor (13) are arranged in the inner part of the outer shell (3), the power supply (12) is connected with the ion air fans (8) through wires, and the speed sensor (13) is connected with a microcontroller through wires.

6. An ion wind device for a disposable glove machine according to claim 5, characterized in that: The microcontroller is connected with the ion air fans (8) through wires, the microcontroller is connected with an adjusting knob (14), and the adjusting knob (14) is arranged on the inclined surface of the outer side of the outer shell (3).

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